新型电力系统视角下空调系统再认识
摘要:构建以新能源为主体的新型电力系统是实现碳中和目标的关键,这一新的系统构建需要“源储网荷”协同互动。空调系统是建筑等终端用户侧的重要用能负载,在新型电力系统构建过程中需要承担哪些新的任务?新型电力系统对空调系统有哪些新要求?空调系统能够发挥什么样的作用?这些问题均亟待解答。为此,本文从新型电力系统视角出发,对空调系统提出的新需求、需承担的新任务及空调系统能够发挥的作用等方面进行了探讨,空调系统在实现自身“源储荷”各环节转变的基础上,应当重视所能发挥的柔性用能作用,成为新型电力系统中的友好负载用户。本研究将为深入认识空调系统在新型电力系统中需做出的变革、可发挥的作用提供有益探索和参考。
关键词:新型电力系统空调系统柔性等效储能“源储网荷”
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[19] 康靖,李雨桐,郝斌,等.多联机空调柔性负荷参与电力系统需求响应的实证研究[J].供用电,2022,39(8):39- 46.
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[2] 舒印彪,陈国平,贺静波,等.构建以新能源为主体的新型电力系统框架研究[J].中国工程科学,2021,23(6):61- 69.
[3] 鲁宗相,林弋莎,乔颖,等.极高比例可再生能源电力系统的灵活性供需平衡[J].电力系统自动化,2022,46(16):3- 16.
[4] 张勇军,羿应棋,李立浧,等.新型低压配电系统特征、关键问题与技术展望[J/OL].电力系统自动化.[2022-12-10].https://kns.cnki.net/kcms/detail/32.1180.TP.20220531.1512.008.html.
[5] 张智刚,康重庆.碳中和目标下构建新型电力系统的挑战与展望[J].中国电机工程学报,2022,42(8):2806- 2818.
[6] 舒印彪,谢典,赵良,等.碳中和目标下我国再电气化研究[J].中国工程科学,2022,24(3):195- 204.
[7] 张涛,刘晓华,刘效辰.双碳目标下车-建筑-电网(VBG)协同互动的探索[J].暖通空调,2023,53(5):1- 11.
[8] 魏一凡,韩雪冰,卢兰光,等.面向碳中和的新能源汽车与车网互动技术展望[J].汽车工程,2022,44(4):449- 464.
[9] 李香龙,赵乐,王瀚秋,等.基于柔性负荷和建筑多能源系统的电网峰谷调节算法[J/OL].沈阳工业大学学报.[2022-12-10].https://kns.cnki.net/kcms/detail/21.1189.T.20220714.1228.004.html.
[10] 刘晓华,张涛,刘效辰,等.面向双碳目标的建筑能源系统再认识[J/OL].力学学报.[2022-12-10].https://kns.cnki.net/kcms/detail/11.2062.O3.20221103.1600.004.html.
[11] 李先庭,赵阳,魏庆芃,等.碳中和背景下我国空调系统发展趋势[J].暖通空调,2022,52(10):75- 83,61.
[12] YAN H Z,ZHANG C,SHAO Z,et al.The underestimated role of the heat pump in achieving China's goal of carbon neutrality by 2060[J/OL].Engineering.[2022-12-10].https://doi.org/10.1016/j.eng.2022.08.015.
[13] WALKER I S,LESS B D,CASQUERO-MODREGO N.Carbon and energy cost impacts of electrification of space heating with heat pumps in the US[J].Energy and buildings,2022,259:111910.
[14] BAECKER B R,CANDAS S.Co-optimizing transmission and active distribution grids to assess demand-side flexibilities of a carbon-neutral German energy system[J].Renewable and sustainable energy reviews,2022,163:112422.
[15] 刘晓华,张涛,刘效辰.如何描述建筑在新型电力系统中的基本特征?——现状与展望[J].暖通空调,2023,53(1):1- 10,124.
[16] 徐科,徐晶,李娟,等.基于暖通负荷集群响应能力的电力系统频率控制策略[J].电力系统及其自动化学报,2022,34(3):37- 44.
[17] 乐慧,李好玥,江亿.用空气源热泵实现农村采暖的“煤改电”同时为电力削峰填谷[J].中国能源,2016,38(11):9- 15.
[18] 陈孝国.时滞效应对空调系统进行需求响应的影响研究[D].北京:北京建筑大学,2022:8- 20.
[19] 康靖,李雨桐,郝斌,等.多联机空调柔性负荷参与电力系统需求响应的实证研究[J].供用电,2022,39(8):39- 46.
[20] 林琳.航站楼多区域客流特征与供冷需求研究[D].北京:清华大学,2022:100- 114.
[21] 清华大学建筑节能研究中心.中国建筑节能年度发展研究报告2018[M].北京:中国建筑工业出版社,2018:57- 75.
Reunderstanding of air conditioning system from perspective of new power system
Abstract: The construction of a new power system with new energy as the main body is the key to achieve the goal of carbon neutrality. The construction of this new system requires the synergistic interaction of “source, storage, network and load”. Air conditioning system is an important energy use load on the end user side such as buildings. What new tasks for the air conditioning system should be undertaken in the construction of new power system? What are the new requirements of the new power system for the air conditioning system? What role can the air conditioning system play? These questions need to be answered. Therefore, from the perspective of the new power system, this paper discusses the new demands, new tasks to be undertaken and the role that the air conditioning system can play. The air conditioning system should pay attention to the flexible energy use role it can play on the basis of realizing the transformation of each link of its own “source, storage and load”, and become a friendly load user in the new power system. This study will provide useful exploration and reference for further understanding of the changes and functions of air conditioning system in the new power system.
Keywords: new power system; air conditioning system; flexibility; equivalent energy storage; “source,storage,network,load”;
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